Magnetic recording system including magnetic recording medium having three-dimensional random orientation of axis of easy magnetization

ABSTRACT

A magnetic recording system includes a magnetic recording medium including a magnetic layer, the magnetic layer being composed of magnetic grains, and a magnetic head including a recording unit and a reproducing unit. An orientation of an axis of easy magnetization of the magnetic grains is three-dimensionally distributed. An average angle between a direction of an axis of easy magnetization of each of the magnetic grains and a surface of the magnetic recording medium is within a range of 20° to 30°. A squareness ratio Mr/Ms of a remanent magnetization Mr of the magnetic recording medium to a saturation magnetization Ms of the magnetic recording medium is equal to 0.5 or more and is equal to 0.6 or less. A recording density of information which is recorded onto the magnetic recording medium is equal to 360 kfci or more.

BACKGROUND OF THE INVENTION

[0001] 1. Field of the Invention

[0002] The invention relates to a magnetic recording system suitable for high density recording and, more particularly, to a magnetic recording system having a recording density of 10 Gigabits or more per square inch.

[0003] 2. Description of the Related Art

[0004] The realization of a large capacity is required more and more in a magnetic disk apparatus as an external magnetic recording system of a computer. To realize the large capacity, as a magnetic head of the magnetic recording system, a recording unit and a reproducing unit are separated, an electromagnetic induction type magnetic head is used in the recording unit, a magneto-resistance effect type head is used in the reproducing unit, and a combination head in which those heads are combined is used. According to the magneto-resistance effect type head, since a reproducing sensitivity is higher than that of the conventional electromagnetic induction type head, a recording bit becomes fine and, even if a leakage flux decreases, an enough reproduction output can be obtained. The development of a very large magneto-resistance effect type head of a spin valve type having a further high reproducing sensitivity is also progressing. A magnetic recording medium is constructed by: a Co alloy magnetic layer made of CoCrTa, CoCrPt, or the like; and a Cr underlayer to control crystal orientation of the magnetic layer. The Co alloy magnetic layer has a hexagonal closest (hcp) lattice structure in which a c axis is used as an axis of easy magnetization and it is considered to be desirable that the direction of axis of easy magnetization is isotropically directed in the plane as for an in-plane magnetic recording medium, and a method of further orienting in the plane (JP-A-62-257618, JP-A63-197018) has been proposed. In case of using the magneto-resistance effect type head as a reproducing head, the further reduction of noises than the conventional ones is required for the medium in order to reproduce not only a signal of the medium but also the noises at a high sensitivity. The medium noises are mainly caused by a disturbance of magnetization in a magnetization transition region between the recording bits and the narrowing of such a region contributes to the reduction of the medium noises. For this purpose, it is effective to make magnetic particles of the magnetic film of the medium fine. When the magnetic particles are made fine, however, it results in that the magnetization thermally fluctuates and the recorded magnetization is attenuated with the elapse of time. Generally, it is known that as a value Ku·V/k·T obtained by dividing the product of a magnetic anisotropy constant Ku and a volume V of particle by the product of a Boltzmann's constant k and a temperature T decreases, thermal instability increases (IEEE Trans. Magn. 30(1994) p4230). Although it is, accordingly, desirable to use a material having a large Ku to obtain the thermal stability, in the conventional medium, the larger the value of Ku is, the more a magnetic anisotropy magnetic field Hk increases, so that a coercive force Hc of the medium also rises. However, generally, it is known that, as a magnetic field of the head upon recording, the magnetic field which is 1.5 to 2 times as high as Hc is needed at the center of the film thickness of the medium. According to the ability of the current magnetic head, as the coercive force Hc of the medium increases, the recording becomes impossible. It is, therefore, demanded to realize a medium such that Ku is large, thermal stability is obtained, further, Hc according to the ability of the recording head can be realized, and a high signal output to noise ratio (S/N ratio) is obtained even in the high density recording.

SUMMARY OF THE INVENTION

[0005] To realize a magnetic recording system suitable for high density magnetic recording, the realization of fine magnetic particles of the magnetic layer of the medium is necessary to reduce noises. An influence by a thermal fluctuation in association with it, however, causes a problem that magnetization is attenuated with the elapse of time. It is sufficient to select a medium material of a large anisotropy constant Ku as one of means for suppressing the influence by the thermal fluctuation. In the conventional technique, the material having large Ku simultaneously shows a high coercive force Hc. However, although an enough large head magnetic field is necessary to record to the medium of high Ku (high Hc), it is becoming difficult to generate an enough magnetic field according to the ability of the current head. According to the invention, even if Ku is increased, Hc can be reduced, so that the thermal fluctuation can be suppressed and a further high signal output to noise ratio (S/N ratio) can be maintained. Particularly, a magnetic recording system suitable to accomplish the recording density of 10 Gigabits or more (magnetization transition length is equal to 70 nm or less) per square inch can be provided.

[0006] According to the invention, there is provided a magnetic recording system comprising: a magnetic recording medium having a magnetic layer formed on a substrate through an underlayer; a driving unit for driving the medium in the recording direction; a magnetic head constructed by a recording unit and a reproducing unit; means for relatively moving the magnetic head to the magnetic recording medium; and recording reproduction signal processing means for performing a signal input to the magnetic head and an output signal reproduction from the magnetic head, wherein the reproducing unit of the magnetic head is constructed by a magneto-resistance effect type head and has a recording magnetization pattern in which a magnetization reversal length of the magnetic recording medium is equal to 70 nm or less, the direction of an axis of easy magnetization of the magnetic particles in the magnetic layer of the magnetic recording medium is three-dimensionally distributed (an axis of easy magnetization is inclined in the film thickness direction for the film surface), and a remanent squareness (Mr/Ms) as a ratio of a remanent magnetization Mr and a saturation magnetization Ms which were measured by applying the maximum magnetic field of the magnetic head in the relative moving direction of the magnetic head and the magnetic recording medium is set to a value within a range from 0.5 to 0.6, thereby enabling Hc to be reduced even if Ku is increased, so that a thermal fluctuation is suppressed and a further high recording density can be accomplished. The reason why Hc can be reduced even if Ku is increased is as follows. Generally, when an angle which is formed by the direction of the axis of easy magnetization and the magnetic field direction is equal to 45° or less, as such an angle increases, a magnetization reversal occurs in a weak magnetic field. By three-dimensionally distributing the direction of the axis of easy magnetization, the average angle between the direction of the head magnetic field and the direction of the axis of easy magnetization increases. Therefore, even if Ku is large, the increase in Hc can be suppressed as compared with the medium in which it is two-dimensionally distributed. A degree of orientation is reflected to Mr/Ms and when it is equal to 0.5, it corresponds to a state where the direction of the axis of easy magnetization is perfectly 3-dimensionally distributed. In the present invention, a range of 0.5 to 0.6 as a value of Mr/Ms corresponds to a region having an orientation that is slightly dominant in the in-plane direction from the perfect 3-dimensional randam orientation.

BRIEF DESCRIPTION OF THE DRAWINGS

[0007]FIG. 1 shows a result in the case where an Mr/Ms (Mr: remanent magnetization, Ms: saturation magnetization) dependency of an S/N ratio (S: reproduction output, N: noises) of a magnetic recording system of the embodiment 1 and S/N ratios of values of Mr/Ms except that of the embodiment are calculated by a Langevin equation and compared;

[0008]FIGS. 2A and 2B are a schematic plan view of the magnetic recording system of the embodiment of the invention and a cross sectional view taken along the line A-A′ in FIG. 2A;

[0009]FIG. 3 is a schematic solid view showing a cross sectional structure of a magnetic head in the magnetic recording system of the invention;

[0010]FIG. 4 shows a medium shape in the embodiment 1;

[0011]FIG. 5 shows the relation between σ and the average value of angles at which the axis of easy magnetization is inclined in the film thickness direction of the medium in case of assuming that an orientation distribution of an axis of easy magnetization is expressed by x²+y²+z²/σ=1 (x: component in the track travelling direction of the axis of easy magnetization, y: component in the track width direction, z: component in the film thickness direction);

[0012]FIG. 6 shows the relation between σ and Mr/Ms (Mr: remanent magnetization, Ms: saturation magnetization) in case of assuming that the orientation distribution of the axis of easy magnetization is expressed by x²+y²+z²/σ=1 (x: component in the track travelling direction of the axis of easy magnetization, y: component in the track width direction, z: component in the film thickness direction);

[0013]FIG. 7 shows a result in the case where an Mr/Ms (Mr: remanent magnetization, Ms: saturation magnetization) dependency of a change ratio of a reproduction output after the elapse of 100 hours of the reproduction output in the magnetic recording systems of the embodiment 1 and except that of the embodiment are calculated by a Monte Carlo method and compared;

[0014]FIG. 8 shows results in the case where time decay of the reproduction output in magnetic recording systems in the embodiments 2 and 3 is compared with those of the conventional magnetic recording system;

[0015]FIG. 9 shows results in the case where the recording density dependency of the S/N ratio in the magnetic recording system in the embodiment 2 is compared with that of the conventional magnetic recording system; and

[0016]FIG. 10 shows results in the case where the recording density dependency of the resolution in the magnetic recording system in the embodiment 2 is compared with that of the conventional magnetic recording system.

DETAILED DESCRIPTION OF THE EMBODIMENTS

[0017] Embodiment 1

[0018]FIGS. 2A and 2B show a schematic plan view and a schematic cross sectional view of a magnetic recording system of an embodiment 1. The system is a magnetic recording system having a well-known structure comprising: a magnetic recording medium 11; a driving unit 12 to rotate it; a magnetic head 13; driving means 14; and a recording reproduction signal processing means 15 of the magnetic head. FIG. 3 shows a schematic diagram of a structure of the magnetic head of the magnetic recording system. The magnetic head is a recording/reproduction separation type head in which an electromagnetic inductive type magnetic head for recording formed on a magnetic head slider substrate 27 and a magneto-resistance effect type head for reproduction are combined. The recording magnetic head is an inductive type thin film magnetic head comprising a pair of recording magnetic poles 21 and 22 and coils 23 which intersect them. The reproducing magnetic head is a magneto-resistance effect type head comprising a magneto-resistance effect sensor 24 and a conductive layer 25 serving as an electrode. A gap layer and a shield layer between the recording magnetic poles are omitted in FIG. 3. A head gap length gl of the electromagnetic inductive type magnetic head for recording is equal to 0.2 μm and a shield interval is equal to 0.2 μm. Under such system conditions, in order to clarify medium magnetic characteristics and a medium structure which can solve the above problems, various examinations were made by using a magnetic recording simulator. Particularly, the relations among a distribution of an axis of easy magnetization of the medium, recording and reproducing characteristics, and an aging change of a reproduction output were examined, so that it has been found that the problems can be solved by a medium having characteristics, which will be explained hereinbelow. The details are shown below. The magnetic recording simulator is based on a magnetic recording calculating program using a Langevin equation (W. F. Brown, Phys. Rev. 130,1677 (1963)) and a calculating program of an aging change of the reproduction output using a Monte Carlo method (Y. Kanai and Charap, IEEE Trans. Magn. 27,4972 (1991)). A particle shape of the medium has a ultrafine hexagonal prism structure having a diameter of 10 nm and a film thickness of 16 nm as shown in FIG. 4 and the particles are arranged without a gap. A magnetic anisotropy of the particles is a uniaxial anisotropy and an orientation distribution of the axis of easy magnetization is considered as a rotary ellipse of x²+y²+z² /σ²=1. (x, y, z) denote a component in the track travelling direction (down-track direction) of the axis of easy magnetization, a component in the track width direction (cross-track direction), and a component in the film thickness direction (medium thickness direction). σ is an arbitrary constant to decide the orientation in the film thickness direction. FIG. 5 shows results in which σ and the average value of angles at which the axis of easy magnetization is inclined in the medium film thickness direction are shown as a graph. The angles were measured from the film surface. Thus, a medium such that as σ is closer to 0, the axis of easiness is distributed at random in the film surface and is hardly oriented in the film thickness direction is obtained. When σ=1, this means that the axis of easy magnetization is three-dimensionally distributed at random (3-dimensional random orientation). If σ is equal to or larger than 1, further, this means that the orientation distribution of the particles is deviated in the film thickness direction. The saturation magnetization Ms is set to be constant (Ms=0.65T). The magnetic anisotropy constant Ku is set to a large value within a range of 1.0 to 2.2×10⁵ J/m³ as the average of the orientation of the axis of easy magnetization is inclined in the film thickness direction so that the coercive force Hc and remanent magnetization Mr of the medium are also set to be constant (Hc=250 kA/m, Mr=0.35T, Mr·δ=5.6 Tnm). The magnitude Hc=250 kA/m of the coercive force is a value obtained by assuming that as a result that the head structure is drawn by a schematic diagram and a head magnetic field is measured by a 3-dimensional magnetostatic field analysis simulator, since the maximum magnetic field intensity is equal to 500 kA/m, if the coercive force has a value of ½ of it, the recording can be sufficiently performed. Under the above conditions, the relation between the parameter σ regarding the inclination of the axis of easy magnetization and Mr/Ms is obtained and the result is shown in FIG. 6. It has consequently been known that as the average of the axis of easy magnetization has the larger inclination in the film thickness direction, namely, as the axis of easy magnetization is 3-dimensionally distributed, Mr/Ms decreases. Recording and reproducing characteristics and thermal fluctuating characteristics are calculated by using the medium having the above magnetic characteristics and the foregoing head. A spacing between the head and the medium at the time of recording/reproduction is set to 45 nm. FIG. 1 shows results of calculations with respect to the relation between the ratio (S/N) of the reproduction output to noises and Mr/Ms in case of a recording density 360 kfci (magnetization transition length=70 nm). Thus, when Mr/Ms lies within a range from 0.5 to 0.6, the S/N ratio has almost the peak value, and even when Mr/Ms is equal to 0.5 or less or is equal to 0.6 or more, the S/N ratio decreases. Further, when the recording density is equal to 360 kfci, although the S/N ratio of 20 dB or more is needed, it has been found that this condition is satisfied when 0.5≦Mr/Ms≦0.6. Subsequently, FIG. 7 shows the reproduction output just after the recording in the case where the recording and reproduction are performed at a recording density of 360 kfci (magnetization transition length=70 nm) and a change (%) of the reproduction output after the medium was left at a room temperature (300K) for 100 hours (time-decay of the reproduction output). Thus, it has been found that when Mr/Ms is equal to 0.6 or less, the reproduction output hardly changes and, when Mr/Ms is equal to 0.6 or more, the reproduction output decreases. This is because it is considered that since Ku decreases in association with an increase in Mr/Ms, a thermal stability factor Ku·V/k·T (Ku: magnetic anisotropy constant, V: volume of particle, k: Boltzmann's constant, T: temperature) also decreases and the recording magnetization is influenced by the thermal fluctuation and demagnetized. Consequently, at the recording density of 360 kfci, by using the medium in which the axis of easy magnetization of particles is 3-dimensionally distributed as to have an average inclination of 200 to 300 (Mr/Ms lies within a range of 0.5 to 0.6) in the film thickness direction for the film surface, a preferable system which has an excellent thermal stability resistance and the S/N ratio is equal to 20 dB or more can be obtained. This invention assumes embodiment 1. A point that the calculation results almost reconstruct the experiment results is shown in next embodiments 2 and 3.

[0019] Embodiment 2

[0020] In a magnetic recording system of an embodiment 2, the head having the same specification as that of the embodiment 1 is used.

[0021] The magnetic recording system is formed by using an RF magnetron sputtering method. A glass substrate is used as a substrate, a substrate temperature is set to 280° C., and an underlayer made of SiO₂ or Al₂O₃ having a thickness of 0.1 μm is formed on the substrate. Subsequently, an argon gas of 5 mTorr is introduced, an electric power of 0.7 kW/cm² is applied, and a magnetic layer CoCrPt having a thickness (δ) of 16 nm is formed. A carbon film having a thickness of 6 nm is further formed as a protection layer on the magnetic layer. Magnetic characteristics of the medium formed in this manner are measured by using a VSM (vibration sample type magnetometer) by applying a reproducing magnetic field of the magnetic head to the medium in the relative moving direction of the magnetic head and the magnetic recording medium. In case of using SiO₂ as an underlayer, the saturation magnetization Ms=0.65T, the remanent magnetization Mr=0.35T, and the remanent squareness Mr/Ms=0.54. Therefore, the product Mr·δ of the film thickness and a residual flux density is equal to Mr·δ=5.6 Tnm. The coercive force is equal to 250 kA/m by the measurement using the same VSM. A magnitude of the magnetic anisotropy constant obtained by the magnetic torque method is equal to 1.8×10⁵ J/m³ and is larger than that of the conventional medium. The value obtained by dividing the sum of the observation particle areas of the medium particles by the number of observation particles is set to an average area (=100 nm²) of the crystal particles and a thermal stability factor Ku·V/k·T is obtained by using a TEM (Transmission Electron Microscopy), so that it is equal to 70 at the room temperature (T=300K). As a result of examining a diffraction peak by using a reflection X-ray diffraction method, although peaks were found in both of [110] and [001], a particularly dominant orientation is not found. Therefore, it has been confirmed that the medium in which the direction of the axis of easy magnetization of the magnetic particles of the magnetic layer is 3-dimensionally distributed is obtained. Magnetic characteristics of the medium formed by using Al₂O₃ as an underlayer are similarly measured by the VSM, so that the saturation magnetization Ms=0.66T, the remanent magnetization Mr=0.35T, and the remanent squarenents ratio Mr/Ms=0.53. Therefore, the product Mr·δ of the film thickness and the residual flux density is equal to Mr·δ=5.6 Tnm. The coercive force is equal to 260 kA/m by the measurement using the same VSM. A magnitude of the magnetic anisotropy constant obtained by the magnetic torque method is equal to 1.8×10 J/m³. The value obtained by dividing the sum of the observation particle areas of the medium particles by the number of observation particles is set to an average area (=100 nm⁻²) of the crystal particles and a thermal stability factor Ku·V/k·T is obtained by using a TEM (Transmission Electron Microscopy), so that it is equal to 70 at the room temperature (T=300K). As a result of examining a diffraction peak by using a reflection X-ray diffraction method, although peaks were found in both of [110] and [001], a particularly dominant orientation is not found. Therefore, it has been confirmed that the medium in which the direction of the axis of easy magnetization of the magnetic particles of the magnetic layer is 3-dimensionally distributed is obtained.

[0022] Comparison results obtained by measuring the time-decay of the reproduction output and the recording and reproducing characteristics by using the magnetic recording system of the invention and the conventional magnetic recording system are shown. The magnetic recording system of the invention is a system comprising the medium using SiO₂ as an underlayer shown above and the recording/reproduction separation type head which is formed by combining an electromagnetic inductive type magnetic head for recording having a head gap length gl=0.2 μm and a magneto-resistance effect type head for reproduction having a shield interval of 0.2 μm. The spacing between the head and the medium is set to 30 nm. In the conventional magnetic recording system, the same head as that of the invention is used and the conventional medium in which the axis of easy magnetization of the particles is distributed in the plane and which is isotropic in the plane is used. As a thickness of magnetic layer, a particle diameter, and Mr·δ (=6.0 Tnm) and Hc (=250 kA/m) among the magnetic characteristics, almost the same values as those of the medium used in the magnetic recording system of the invention are used. However, since Ms=0.5T, the remanent squareness ratio Mr/Ms 0.7, Ku 1.4×10⁵ J/m³, and Ku·V/k·T=54, it is presumed that the thermal decay are worse than those of the medium used in the invention. FIG. 8 shows a time-decay of the reproduction output at a linear recording density of 400 kfci. It has consequently been found that the reproduction output deteriorates by 7% in the conventional magnetic recording system after 100 hours and that it hardly deteriorates in the magnetic recording system of the invention. Since the time-decay is larger as the magnetic recording density is higher, it is possible to presume that there is hardly a time-decay after 100 hours at the recording density of 360 kfci lower than that of 400 kfci of the invention. That is, the calculation results of the embodiment 1 preferably coincide with the experiment results. Subsequently, the recording and reproducing characteristics of the magnetic recording system are compared. FIG. 9 shows a dependency of the S/N ratio of the reproduction output to the noises on the recording density. It has, consequently, been known that although the S/N ratio of the magnetic recording system of the invention at the low recording density is lower than that of the conventional magnetic recording system, at a recording density of 300 kfci or more, the S/N ratio of the system of the invention is higher. It has also been found from the diagram that S/N=20 dB at the recording density of 360 kfci (magnetization transition length=70 nm) and is almost equal to the S/N ratio of the embodiment 1. That is, it has also been found from this result that the calculation results of the embodiment 1 preferably coincide with the experiment results. Further, in case of the recording density of 360 kfci, although the S/N=20 dB or more is necessary for the system, in the conventional system, the limit of the recording density is equal to 330 kfci and 10 Gigabits per square inch cannot be accomplished. However, in the system of the embodiment, the recording density is equal to 360 kfci and the recording of 10 Gigabits per square inch can be performed. FIG. 10 shows a dependency of the resolution on the recording density. The resolution denotes a value in which an output E_(2f) of the high recording density is normalized by a reproduction output E_(1f) at the low recording density (50 kfci). Although the reproduction output decreases in association with an increase in recording density, in the magnetic recording system of the invention, a decreasing rate is small. When the recording density is equal to 200 kfci or more, it has been found that the resolution as a ratio of the output E_(1f) of the low recording density and the output E_(2f) of the high recording density is higher than that of the conventional system. Particularly, when the recording density is equal to 360 kfci or more, since the resolution of 20% or more is necessary, the above conditions cannot be satisfied in case of systems other than the system according to the invention. It has consequently been found that the magnetic recording system of the invention is thermally stable and suitable for the high density magnetic recording in which the recording density is equal to 360 kfci or more, namely, the magnetization transition length is equal to 70 nm or less. Further, the time-decay and recording and reproducing characteristics of the reproduction output of the magnetic recording system using the medium in which the underlayer is made of Al₂O₃ are measured, so that results which are almost equivalent to those of the magnetic recording system using the medium in which the underlayer is made of SiO₂ are obtained. It has also been found that the system is thermally stable as compared with the conventional magnetic recording system and is suitable for the high density magnetic recording.

[0023] Embodiment 3

[0024] An embodiment 3 shows a comparison example examined while changing Mr/Ms for the embodiment 2. In a magnetic recording system of the embodiment 3, the same head as that of the embodiment 1 is used and as a medium, the same glass substrate, magnetic layer, and protection layer as those in the embodiment 2 are formed under substantially the same film forming conditions as those of the embodiment 2 except that a Zr or Al film having a thickness of 0.1 μm is provided as an underlayer. According to the medium formed by using Zr as an underlayer, the saturation magnetization is equal to Ms=0.60T, the residual magnetization measured by the VSM is equal to Mr=0.32T, and the remanent squareness is equal to Mr/Ms=0.53. According to the measurement by the same VSM, the coercive force is equal to 280 kA/m. The magnitude of the magnetic anisotropy constant Ku obtained by the magnetic torque method is equal to 1.7×10⁵ J/m³ and is larger than that of the conventional medium. The magnetic characteristics of the medium formed by using Al as an underlayer are almost the same as those of the medium using Zr as an underlayer. Subsequently, the value obtained by dividing the sum of the observation particle areas of the medium particles by the number of observation particles is set to the average area (=100 nm²) of the crystal particles and Ku·V/k·T serving as a thermal stability factor is obtained by using the TEM (Transmission Electron Microscopy), so that it is equal to 66 at the room temperature (T=300K). Even in this magnetic layer, the medium in which the direction of the axis of easy magnetization of the magnetic particles of the magnetic layer is 3-dimensionally distributed is obtained in a manner similar to the embodiment 2. The time-decay of the reproduction output is examined in a manner similar to the embodiment 2, so that the output after the elapse of 100 hours is reduced by about 0.5% as shown in FIG. 8. Further, as a comparison example, the time-decay and S/N ratio of the reproduction output of the magnetic recording system using the same head as that of the embodiment 2 and the medium having substantially the same layer structure and formed under substantially the same film forming conditions as those in the embodiment 2 except that a Ti film having a thickness of 0.05 μm is used as an underlayer are measured. Although the magnetic characteristics of the medium used for comparison exhibit almost the same values, namely, Mr·δ=5.6 Tnm, Hc=240 kA/m, and Ku·V/k·T=75 as those in the embodiment 1 by the VSM measurement, Ms=0.87 and the remanent squareness is equal to Mr/Ms=0.4, so that the remanent squareness fairly deteriorates. Although the time-decay of the reproduction output is almost the same as that in the embodiment 2, since the noises increase in association with the deterioration of the output as shown in FIG. 9, the SIN ratio fairly deteriorates. It has, therefore, been found that in case of the remanent squareness is equal to 0.5 or less, it is not suitable for the high density magnetic recording.

[0025] According to the magnetic recording system using the magnetic recording medium in which the direction of the axis of easy magnetization of the magnetic particles in the magnetic layer of the invention is 3-dimensionally destributed as mentioned above, in the case where the recording magnetization pattern in which the magnetization transition length of the magnetic recording medium is equal to 70 nm or less is recorded, the medium of high Ku and low Hc can be realized. Excellent characteristics for the S/N ratio, resolution, and thermally stable can be obtained. 

What is claimed is:
 1. A magnetic recording system comprising: a magnetic recording medium including a magnetic layer, the magnetic layer being composed of magnetic grains; and a magnetic head including a recording unit and a reproducing unit; wherein an orientation of an axis of easy magnetization of the magnetic grains is three-dimensionally distributed; and wherein a squareness ratio Mr/Ms of a remanent magnetization Mr of the magnetic recording medium to a saturation magnetization Ms of the magnetic recording medium is equal to 0.5 or more and is equal to 0.6 or less.
 2. A magnetic recording system according to claim 1, wherein a recording density of information which is recorded onto the magnetic recording medium is equal to 360 kfci or more.
 3. A magnetic recording system according to claim 1, wherein a magnetization transition length of a recording magnetization pattern which is recorded onto the magnetic recording medium is equal to 70 nm or less.
 4. A magnetic recording system according to claim 1, wherein the remanent magnetization Mr and the saturation magnetization Ms are measured by applying a magnetic field to the magnetic recording medium with the recording unit in a direction of relative movement between the magnetic head and the magnetic recording medium.
 5. A magnetic recording system according to claim 1, wherein respective orientations of respective axes of easy magnetization of the magnetic grains have a three-dimensional distribution, thereby causing the orientation of the axis of easy magnetization of the magnetic grains to be three-dimensionally distributed.
 6. A magnetic recording system according to claim 1, wherein the orientation of the axis of easy magnetization of the magnetic grains has a three-dimensional distribution defined by the following equation: x ² +y ² +z ²/σ²=1 where x is a component of the axis of easy magnetization in a track travelling direction of the magnetic recording medium, where y is a component of the axis of easy magnetization in a track width direction of the magnetic recording medium, where z is a component of the axis of easy magnetization in a medium thickness direction of the magnetic recording medium, and where σ is an arbitrary constant which controls the orientation of the axis of easy magnetization of the magnetic grains relative to the medium thickness direction.
 7. A magnetic recording system according to claim 1, wherein the squareness ratio Mr/Ms which is equal to 0.5 or more and is equal to 0.6 or less enables a S/N (signal-to-noise) ratio of a reproduction output of the magnetic head to be at least 20 dB.
 8. A magnetic recording system comprising: a magnetic recording medium including a magnetic layer, the magnetic layer being composed of magnetic grains; and a magnetic head including a recording unit and a reproducing unit; wherein an average angle between a direction of an axis of easy magnetization of each of the magnetic grains and a surface of the magnetic recording medium is within a range of 200 to
 300. 9. A magnetic recording system according to claim 8, wherein a recording density of information which is recorded onto the magnetic recording medium is equal to 360 kfci or more.
 10. A magnetic recording system according to claim 8, wherein a magnetization transition length of a recording magnetization pattern which is recorded onto the magnetic recording medium is equal 70 nm or less.
 11. A magnetic recording system according to claim 8, wherein respective orientations of respective axes of easy magnetization of the magnetic grains have a three-dimensional distribution.
 12. A magnetic recording system according to claim 11, wherein the three-dimensional distribution of the respective orientations of the respective axes of easy magnetization of the magnetic grains is such that the average angle between the direction of the axis of easy magnetization of each of the magnetic grains and the surface of the magnetic recording medium is within the range of 20° to 30°.
 13. A magnetic recording system according to claim 11, wherein the three-dimensional distribution of the respective orientations of the respective axes of easy magnetization of the magnetic grains is defined by the following equation: x ² +y ² +z ²/σ²=1 where x is a component of the respective axes of easy magnetization of the magnetic grains in a track travelling direction of the magnetic recording medium, where y is a component of the axes of easy magnetization of the magnetic grains in a track width direction of the magnetic recording medium, where z is a component of the axes of easy magnetization of the magnetic grains in a medium thickness direction of the magnetic recording medium, and where σ is an arbitrary constant which controls the respective orientations of the axes of easy magnetization of the magnetic grains relative to the medium thickness direction.
 14. A magnetic recording system according to claim 8, wherein the average angle between the direction of the axis of easy magnetization of each of the magnetic grains and the surface of the magnetic recording medium within the range of 20° to 30° enables a S/N (signal-to-noise) ratio of a reproduction output of the magnetic head to be at least 20 dB. 